Thermodynamic and structural determinants of calcium-independent interactions of Calmodulin

Feldkamp, Michael Dennis

01 July 2010

Calmodulin (CaM) is an essential protein found in all eukaryotes ranging from vertebrates to unicellular organisms such as Paramecia. CaM is a calcium sensor protein composed of two domains (N and C) responsible for the regulation of numerous calcium-mediated signaling pathways. Four calcium ions bind to CaM, changing its conformation and determining how it recognizes and regulates its cellular targets. Since the discovery of CaM, most studies have focused on the role of its calcium-saturated form. However, an increasing number of target proteins have been discovered that preferentially bind apo (calcium-depleted) CaM. My study focused on understanding how apo CaM recognizes drugs and protein sequences, and how those interactions differ from those of calcium-saturated CaM. I have used spectroscopic methods to explore CaM binding the drug Trifluoperazine (TFP) and the IQ-motif of the type 2 Voltage-Dependent Sodium Channel (Nav1.2IQp). These studies have shown that both TFP and Nav1.2IQp preferentially bind to the "semi-open" conformation of apo CaM. TFP was shown to be an unusual allosteric effector of calcium binding to CaM. Using 15N-HSQC NMR spectroscopy, I determined the stoichiometry of TFP binding to apo Cam to be 2:1 and to (Ca2+)4-CaM to be 4:1 TFP:CaM. That difference in stoichiometry determined whether TFP decreased or increased the affinity of CaM for calcium. Analysis of residue-specific chemical shift differences indicated that TFP binding to apo and (Ca2+)4-CaM perturbed the C-domain more than the N-domain, prompting high-resolution structural studies of the isolated C-domain of CaM. Crystallographic studies of TFP bound to a calcium-saturated C-domain fragment of CaM (CaM76-148) revealed that CaM adopted an "open" tertiary conformation. The unit cell contained two protein and 4 drug molecules. The orientation of TFP revealed that its trifluoromethyl group was found in two alternative positions (one in each protein in the unit cell), and that Met 144 acted as a gatekeeper to select the orientation of TFP. In contrast to TFP binding to the "open" conformation of calcium-saturated CaM76-148, my NMR studies showed that TFP bound the "semi-open" conformation of apo CaM76-148. TFP interacted with CaM residues near the perimeter of the hydrophobic pocket, but did not contact residues that are solvent-accessible only in the "open" form. Allosteric effects due to TFP binding were observed in the calcium-binding loops of apo CaM76-148. These properties suggest that TFP may antagonize interactions between apo CaM and target proteins such as ion channels that preferentially bind apo CaM. Nav1.2, is responsible for the passage of Na+ ion across cellular membranes. Apo binding of CaM to Nav1.2 poises it for action upon calcium release in the cell. My NMR studies of CaM binding to the Nav1.2 IQ-motif sequence (Nav1.2IQp) showed that the C-domain of apo CaM was necessary and sufficient for binding. My high-resolution structure of the isolated C-domain of CaM bound to Nav1.2IQp revealed that the domain adopted a "semi-open" conformation. At the interface between the IQ-motif and CaM, the highly conserved I and two Y residues of Nav1.2IQp interacted with hydrophobic residues of CaM, while the invariant Q residue interacted with residues in the loop between helices F and G of CaM. This is the first CaM-IQ complex to be determined by NMR; the only other available structure of apo CaM bound to an IQ-motif was determined crystallographically. To accomplish its regulatory roles in response to cellular Ca2+ fluxes, CaM has evolved multiple binding interfaces that are allosterically linked to its Ca2+-ligation state. My studies of CaM binding to TFP and NaV1.2 demonstrate the versatility of CaM functioning as a regulatory protein comprised of domains having separable functions.

Calmodulin

Electrostatics

Trifluoperazine

Voltage Dependent Sodium Channel

Biochemistry

Investigation of the Mechanism of Substrate Transport by the Glutamate Transporter EAAC1

Barcelona, Stephanie Suazo

01 January 2007

The activity of glutamate transporters is essential for the temporal and spatial regulation of the neurotransmitter concentration in the synaptic cleft which is critical for proper neuronal signaling. Because of their role in controlling extracellular glutamate concentrations, dysfunctional glutamate transporters have been implicated in several neurodegenerative diseases and psychiatric disorders. Therefore, investigating the mechanism of substrate transport by these transporters is essential in understanding their behavior when they malfunction. A bacterial glutamate transporter homologue has been successfully crystallized revealing the molecular architecture of glutamate transporters. However, many important questions remain unanswered. In this thesis, I will address the role of D439 in the binding of Na+, and I will identify other electrogenic steps that contribute to the total electrogenicity of the transporter cycle. The role of D439 in the binding of Na+ to the transporter was explored previously in this lab. While it was proposed that the effect of D439 in Na+ binding is indirect, the results described in this thesis provides added support to this work. Here, I will show that the D439 mutation changed the pharmacology of EAAC1 such that THA was converted from a transported substrate to a competitive inhibitor. I will also show that Na+ binding to the substrate-bound mutant transporter occurred with the same affinity as that of Na+ to the substrate-bound wild-type transporter. Therefore, based on these results, D439 is not directly involved in the binding of Na+ to the substrate-bound transporter, but that its effect is rather indirect through changing the substrate binding properties. Na+ binding steps to the empty transporter and to the glutamate-bound EAAC1 contribute only 20% of the total electrogenicity of the glutamate transporter reactions cycle. While K+-induced relocation has been proposed to be electrogenic, there is no experimental evidence that supports it. In this work, I will show that the K+-induced relocation of the empty transporter is electrogenic. Moreover, the results in this work show that the K+-dependent steps are slower than the steps associated with the Na+/glutamate translocation suggesting that the K+-induced relocation determines the transporter?s properties at steady state.

Mode of action studies on pentenediols and tamoxifen with mitochondria / ペンテンジオール類およびタモキシフェンのミトコンドリアにおける作用機構研究

Unten, Yufu

23 March 2022

京都大学 / 新制・課程博士 / 博士(農学) / 甲第23954号 / 農博第2503号 / 新制||農||1091(附属図書館) / 学位論文||R4||N5389(農学部図書室) / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授 三芳 秀人, 教授 宮川 恒, 教授 森 直樹 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DGAM

voltage-dependent anion channel

mitochondria

chemicalbiology

bioenergetics

610

Elucidation of subcellular regulation of voltage-dependent calcium channel functions via β subunit interacting molecules / 電位依存性Ca2+チャネルβサブユニット相互作用タンパク質による、細胞内局所的なCa2＋チャネル機能調節機構の解明に関する研究

Mitsuru, Hirano

24 July 2017

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第20633号 / 工博第4371号 / 新制||工||1679(附属図書館) / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 森 泰生, 教授 浜地 格, 教授 跡見 晴幸 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

voltage dependent Ca2+ channel

Rab3-interacting molecule

neurotransmitter release

voltage dependent inactivation

total internal reflection fluorescence

nuclear fraction

co-immunoprecipitation

500

Voltage-dependent anion channels (VDAC) in the plasma membrane induce apoptosis

Akanda, Nesar

January 2006

Apoptosis, or programmed cell death, is essential for proper development and functioning of the body systems. During development, apoptosis plays a central role to sculpt the embryo, and in adults, to maintain tissue homeostasis by eliminating redundant, damaged or effete cells. Therefore, a tight regulation of this process is essential. Cell shrinkage associated efflux of K+ and Cl– through plasma membrane ion channels is an early event of apoptosis. However, little is known about these fluxes. The aim of this thesis was to investigate ion channels in the plasma membrane of neurons undergoing apoptosis. We studied differentiated (the mouse hippocampal cell line HT22, the human neuroblastoma cell line SK-N-MC, and rat primary hippocampal neurons) and undifferentiated (rat primary cortical neural stem cells cNSCs) cells with the patch-clamp technique. All cell types displayed a low electrical activity under control conditions. However, during apoptosis in differentiated neurons, we found an activation of a voltage-dependent anion channel. The conductance of the channel is 400 pS, the voltage dependence of the opening is bell shaped with respect to membrane voltage with a maximum open probability at 0 mV, and the Cl− to cation selectivity is >5:1. These biophysical properties remind about the voltage-dependent anion channel normally found in the outer mitochondrial membrane (VDACmt). Hence, we call our apoptosis-inducing plasma membrane channel VDACpl. The molecular identity of the channel was corroborated with the specific labelling of different anti-VDAC antibodies. Block of this channel either with antibodies or with sucrose prevented apoptosis, suggesting a critical role for VDACpl in the apoptotic process. VDACpl is a NADH (-ferricyanide) reductase in control cells. We found that the enzymatic activity is altered while the VDACpl channel is activated during apoptosis. Surprisingly, in cNSCs we did not find any activation of VDACpl, no VDACpl-specific labelling, no enzymatic activity, and no prevention of apoptosis with VDACpl-blocking strategies. Instead, we found an activation of a voltage-independent 37 pS ion channel, and that the Cl– channel blocker DIDS prevented apoptosis in cNSCs. Our finding that activation of VDACpl is critical for apoptosis in differentiated neurons hopefully can lead to new strategies in the treatment of several diseases related to apoptosis.

Physiology

Apoptosis

Cell membrane

Hippocampus

Membrane potentials

Neurons

Voltage-dependent anion channels

Medicine

Medicin

Voltage-dependent anion channels (VDAC) in the plasma membrane induces apoptosis /

Akanda, Nesar,

January 2006

Diss. (sammanfattning) Linköping : Linköpings universitet, 2006. / Härtill 4 uppsatser.

Molecular elucidation of the physiological significance of Ca2+ channelsome in neuronal function / 神経機能におけるCa2+チャネルソームの生理的意義の分子解明に関する研究

Takada, Yoshinori

24 November 2015

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第19376号 / 工博第4121号 / 新制||工||1635(附属図書館) / 32390 / 新制||工||1635 / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 森 泰生, 教授 梅田 眞郷, 教授 濵地 格 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

Ca2+ channelsome

neurotransmitter release

voltage dependent Ca2+ channels

RIM

spinocerebellar ataxia type 6

500

Expression of Neuronal Proteins in a Differentiating Human Neuroblastoma Cell Line (IMR32): Insights into Neuronal Development and Disease

Chen, Ya

January 2006

No description available.

Biology, Neuroscience

neuronal proteins

voltage-dependent calcium channel

neuroblastoma cell line

IMR32 cells

The Electrical Properties of Bufo marinus Na+, K+-ATPase

Hao, Jingping

January 2009

No description available.

Biology

Na, K-ATPase

voltage dependent

ouabain inhibition

tetraethylammonium

the third Na binding site

REGULATION OF L-TYPE VOLTAGE-DEPENDNET CALCIUM CHANNELS BY THE REM GTPASE

Pang, Chunyan

01 January 2008

The Rem, Rem2, Rad, and Gem/Kir GTPases, comprise a novel subfamily of the small Ras-related GTP-binding proteins known as the RGK GTPases, and have been shown to function as potent negative regulators of high voltage-activated (HVA) Ca2+ channels upon overexpression. HVA Ca2+ channels modulate Ca2+ influx in response to membrane depolarization to regulate a wide variety of cellular functions and they minimally consist of a pore-forming α1 subunit, an intracellular β subunit, and a transmembrane complex α2/δ subunit. While the mechanisms underlying RGK-mediated Ca2+ channel regulation remain poorly defined, it appears that both membrane localization and the binding of accessory Ca2+ channel β subunits (CaVβ) are required for suppression of Ca2+ channel currents. We identified a direct interaction between Rem and the L-type Cavα1 C-terminus (CCT), but not the CCT from CaV3.2 T-type channels. Deletion mapping studies suggest that the conserved CB-IQ domain is required for Rem:CCT association, a region known to contribute to both Ca2+-dependent channel inactivation and facilitation through interactions of Ca2+-bound calmodulin (CaM) with the proximal CCT. Furthermore, both Rem2 and Rad GTPases display similar patterns of CCT binding, suggesting that CCT represents a common binding partner for all RGK proteins. While previous studies have found that association of the Rem C-terminus with the plasma membrane is required for channel inhibition, it is not required for CaVβ- subunit binding. However, Rem:CCT association is well correlated with the plasma membrane localization of Rem and more importantly, Rem-mediated channel inhibition upon overexpression. Moreover, co-expression of the proximal CB-IQ containing region of CCT (residues 1507-1669) in HIT-T15 cells partially relieves Rem blockade of ionic current. Interestingly, Ca2+/CaM disrupts Rem:CCT association in vitro. Moreover, CaM overexpression partially relieves Rem-mediated L-type Ca2+ channel inhibition and Rem overexpression alters the kinetics of calcium-dependent inactivation. Together, these data suggest that the association of Rem with the CCT represents a crucial molecular determinant for Rem-mediated L-type Ca2+ channel regulation and provides new insights into this novel channel regulatory process. These studies also suggest that instead of acting as complete Ca2+ channel blockers, RGK proteins may function as endogenous regulators for the channel inactivation machinery.

RGK GTPase

Voltage-dependent calcium channels

Cavá1 C-terminus (CCT)

Calmodulin

Calcium-dependent inactivation

Chemistry

Medical Biochemistry